热力学及动力学因素对L-S相转化法制备非对称膜结构与性能的影响
作者:孙本惠
单位: 北京化工大学材料科学与工程学院
关键词: 非对称膜;相转化; 铸膜液结构; 脱溶剂速率; 热力学; 动力学
DOI号:
分类号: TQ028.8
出版年,卷(期):页码: 2010,30(1):0-0

摘要:
采用L-S相转化法制备非对称型分离膜的结构与性能取决于其制膜过程的热力学及动力学因素。讨论了聚合物分子量及浓度、溶剂及溶剂化作用、添加剂、铸膜液温度等热力学因素对铸膜液结构的影响,以及溶剂蒸发速度、凝胶速度等动力学因素对于脱溶剂速度的影响,综述了相关的热力学及动力学影响因素的表征方法。
This article defined and provided an overview of the essential affecting factors for the structure and performances of polymeric membranes with asymmectric structure prepared by L-S phase inversion process. The effect of vital thermodynamic factors,  including the molecular weight and concentration of polymer, the solvent and its solvation, the additive selection, and the temperature of casting solution on the structure of casting solution; as well as the impact of critical kinetic factors, such as the solvent evaporation rate and gelation rate on the desolvation rate of the nascent membrane, were systemetically discussed. The methods to charicterize the relavent thermodynamic and kinetic affecting factors were also reviewed.

基金项目:

作者简介:
孙本惠(1943- ),江苏扬州人,教授,博士生导师,从事膜材料的制备和改性、分离膜制备方法、膜结构与性能的调控及优化研究。

参考文献:
[1] Loeb S, Sourirajan S. Sea water demineralization by means of an osmotic membrane[J]. Adv. Chem. Ser. 1963, 38:117-132
[2] Rudin A, Johnston H. Prediction of Viscosities of Concentrated Polymer Solutions [J]. Journal of Paint Technology, 1971, 43: 39-47.
[3] Kesting R E. The four tiers of structure in integrally skinned phase inversion membranes and their relevance to the various separation regimes[J]. Journal of applied polymer science,1990, 41: 2739-2752.
[4] 祝振鑫, Matsuura T. 关于用相转化法制备的反渗透膜、超滤膜和微滤膜其表明孔形成机理的讨论[A]. 第一届全国膜和膜过程学术报告会文集[C],1991,39-42.
[5] 孙本惠. 聚氯乙烯微孔膜的研究[A],全国分离膜及膜过程学术大会论文集[C],中国海水淡化及水再利用学会,湖州,1986,11,2-5.
[6] Wu G Y, Sun B H, Dai W G. Study on PVC ultrafiltration membrane[A], Symposium on Advances in Reverse Osmosis and Ultrafiltration[C], Toronto, CANADA: the Third Chemical Congress of North American Continent, 1988: 35-51,
[7] Wu G Y, Sun B H, Dai W G. Preparation of PVC UF membrane and the effect of PVC casting solution on membrane properties[J], Journal of Polymer. Materials, 1989, 6:127-133.
[8] Wu G Y, Sun B H, Guo L. Investigation on the rate of solvent evaporation and the technologic parameter[J], Journal of Polymer. Materials, 1989, 6:151-158.
[9] Sun B H. Study on the kinetics of gelation in asymmetric membrane formation via phase inversion[A], The Second Joint Meeting on Applied Science and Technology[C], Beijing, Beijing Univ of Chem Tech, 1992, 128-131.
[10] 孙本惠,杨林. 共混型高分子合金膜[A],北京膜学会成立三周年论文报告会论文集[C],北京:北京膜学会,1994,48-49.
[11] 孙本惠,杨林. 共混型高分子合金膜体系相容性及其表征[A],北京膜学会成立三周年论文报告会论文集[C],1994, 50-51.
[12] 孙本惠,杨婷,孙斌. 第二聚合物(P2)对PVC/P2合金膜结构与性能的影响[A],中国膜工业协会首届学术报告会论文集[C],1995, 190-193.
[13] Yang Y, Sun B, Song Y J. Effect of the compatibility on the performance of PSF/SPSF alloy membrane[A], Preprints of international conference on membrane science and technology[C], Beijing, The Chinese Academy of Science, 1998,200-201.
[14] Sun B P, Sun B H. Effect of compatibility of PVC/P2 alloy system on membrane structure and performance[A]. Li N N, et al. Advanced Membrane Technology[C]. New York, USA: ACS, 2003:267-278
[15] Gu X Y, Sun B H. Effect of coagulation condition on the structure and property of the PVC/PAN alloy membranes[J].  Polymeric Materials Sciences and Engineering, 2002, 86: 239-240.
[16] Gu X Y, Sun B H. Improvement on the hydrophilicity of the PVC alloy membranes[J], Polymeric Materials Sciences and Engineering, 2002, 86: 238-239.
[17] Gu X Y, Sun B H. Influence of the compatibility on the performance of the PVC alloy membranes[J], Polymeric Materials Sciences and Engineering, 2002, 86: 241-242.
[18] Sun B H. Prediction and characteriction of the compatibility of polymers in polymer alloy membranes[R]. Anaheim USA: The 227th ACS National Meetng, 2004.
[19] Sun B H, Impacts of membrane technology on sustainable development of the globle economy[R]. Beijing CHINA: Keynote Lecture at the China/USA/Japan Joint Chemical Engineering Conference, 2005.
[20] 杨婷. 高分子合金分离膜的研究[D]. 北京: 北京化工学院,1995.
[21] 孙斌. 体系相容性与PVC/P2合金膜结构-性能相关性[D]. 北京: 北京化工大学,1998.
[22] 杨勇. 聚砜合金膜材料设计及结构设计[D]. 北京: 北京化工大学,1998.
[23] 宋玉军. 芳香聚酰胺超薄复合型纳滤膜(NF-TFC)的研究[D]. 北京: 北京化工大学,2000.
[24] 朱芸林. PVC/P2、PAN/P2非对称型合金微滤膜[D]. 北京: 北京化工大学,2002.
[25] 谷晓昱. 聚氯乙烯合金分离膜研究[D]. 北京: 北京化工大学,2002.
[26] 赵晨阳. PVC/P2、CA/PAN非对称型合金微滤膜[D]. 北京: 北京化工大学,2003.
[27] 唐广军. 聚偏氟乙烯合金分离膜[D]. 北京: 北京化工大学,2004.
[28] Strathmann H, Scheible P, Baker R W. A rationale for the preparation of Loeb-Sourirajan-type cellulose acetate membranes[J]. Journal of applied polymer science, 1971, 15:811-828.
[29] Strathmann H, Kock K, Aamar P. The formation mechanism of asymmetric membranes[J]. Desalination, 1975, 16: 179-203.
[30] Kunst B, Sourirajan S. Evaporation rate and equilibrium phase separation data in relation to casting conditions and performance of porous cellulose acetate reverse osmosis membranes[J]. Journal of applied polymer science, 1970, 14: 1983- 1996.
[31] 武冠英,孙本惠,郭林. 聚氯乙烯超滤膜的溶剂蒸发速度影响研究[J]. 应用化学,1988, 5:48-52
[32] Frommer M A, Feiner I, Kedem O. The mechanism for mormation of “skinned” membranes. II. Equilibrium preperties and osmotic flows determining membrane structure[J]. Desalination, 1970, 7: 393-402.
[33] Rosenthal U, Nechushtan J, Kedem A. An apparatus for studying the mechanism of membrane formation[J]. Desalination, 1971, 9: 193-200.
[34] Frommer M A, Matz R, Rosenthal U. Mechanism of formation of reverse osmosis membranes. Precipitation of cellulose acetate membranes in aqueous solutions[J]. Ind eng Chem prod res dev, 1971, 10:193-196.
[35] Strarhmann H, Kock K, Baker B W. The formation mechanism of asymmetric membranes[J]. Desalination, 1975, 16: 179-203.
[36] Strathmann H. Preduction of microporous media by phase inversion process[A]. Materials science of synthetic membranes[C]. Washington, D C. USA: ACS, 1985.
[37] Reuvers A J, ven den Berg J W A, Smolder C A. Formation of membranes by means of immersion precipition. Part I. A model to describe mass transfer during immersion precipitation[J]. Journal of membrane science, 1987, 34: 67-86.
[38] Reuvers A J, Smolder C A. Formation of membranes by means of immersion precipition. Part II. The mechanism of formation of membranes prepared from the system cellulose acetate-acetone-water[J]. Journal of membrane science, 1987, 34: 45-65.
[39] Kang Y S, Kim H J, Kim U Y. Asymmetric membrane formation via immersion precipitation method[J]. Journal of membrane science, 1991, 60: 219-232.
[40] Kim H J, Tyagi R K, Fouida A E. The kinetic-study for asymmetric membrane formation via phase-inversion process[J]. Journal of applied polymer science, 1996, 62: 621-629.
[41] Yao C W, Burford R P. Effect of coagulation conditions on structure and properties of membranes from aliphatic polyamides[J]. Journal of membrane science, 1998, 38: 113-125.
[42] 孙本惠. 用相转换法制备非对称膜的凝胶动力学研究[J]. 水处理技术,1993,6:308-312.
[43] 孙本惠. 用相转换法制备非对称膜的凝胶速度-膜结构的相关性表征[J]. 水处理技术,1993,6:313-318.
[44] 孙本惠,孙斌. 非对称膜的凝胶速度及膜结构的影响因素[J]. 水处理技术,1995,2:67-72.
[45] Matz R. The structure of cellulose acetate membranes 1. The development of porous structures in anisotropic membranes [J]. Desalination, 1972, 10:1-15.

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